40 research outputs found
Crystallization and preliminary crystallographic study of human CksHs1: A cell cycle regulatory protein
Structural basis for branching-enzyme activity of glycoside hydrolase family 57: Structure and stability studies of a novel branching enzyme from the hyperthermophilic archaeon Thermococcus Kodakaraensis KOD1.
Branching enzymes (BEs) catalyze the formation of branch points in glycogen and amylopectin by cleavage of α-1,4 glycosidic bonds and subsequent transfer to a new α-1,6 position. BEs generally belong to glycoside hydrolase family 13 (GH13); however TK1436, isolated from the hyperthermophilic archaeon Thermococcus kodakaraensis KOD1, is the first GH57 member, which possesses BE activity. To date, the only BE structure that had been determined is a GH13-type from Escherichia coli. Herein, we have determined the crystal structure of TK1436 in the native state and in complex with glucose and substrate mimetics that permitted mapping of the substrate-binding channel and identification of key residues for glucanotransferase activity. Its structure encompasses a distorted (β/α)(7)-barrel juxtaposed to a C-terminal α-helical domain, which also participates in the formation of the active-site cleft. The active site comprises two acidic catalytic residues (Glu183 and Asp354), the polarizer His10, aromatic gate-keepers (Trp28, Trp270, Trp407, and Trp416) and the residue Tyr233, which is fully conserved among GH13- and GH57-type BEs. Despite TK1436 displaying a completely different fold and domain organization when compared to E. coli BE, they share the same structural determinants for BE activity. Structural comparison with AmyC, a GH57 α-amylase devoid of BE activity, revealed that the catalytic loop involved in substrate recognition and binding, is shortened in AmyC structure and it has been addressed as a key feature for its inability for glucanotransferase activity. The oligomerization has also been pointed out as a possible determinant for functional differentiation among GH57 members
A new variant of the Ntn hydrolase fold revealed by the crystal structure of L-aminopeptidase D-ala-esterase/amidase from Ochrobactrum anthropi.
BACKGROUND: The L-aminopeptidase D-Ala-esterase/amidase from Ochrobactrum anthropi (DmpA) releases the N-terminal L and/or D-Ala residues from peptide substrates. This is the only known enzyme to liberate N-terminal amino acids with both D and L stereospecificity. The DmpA active form is an alphabeta heterodimer, which results from a putative autocatalytic cleavage of an inactive precursor polypeptide. RESULTS: The crystal structure of the enzyme has been determined to 1.82 A resolution using the multiple isomorphous replacement method. The heterodimer folds into a single domain organised as an alphabetabetaalpha sandwich in which two mixed beta sheets are flanked on both sides by two alpha helices. CONCLUSIONS: DmpA shows no similarity to other known aminopeptidases in either fold or catalytic mechanism, and thus represents the first example of a novel family of aminopeptidases. The protein fold of DmpA does, however, show structural homology to members of the N-terminal nucleophile (Ntn) hydrolase superfamily. DmpA presents functionally equivalent residues in the catalytic centre when compared with other Ntn hydrolases, and is therefore likely to use the same catalytic mechanism. In spite of this homology, the direction and connectivity of the secondary structure elements differ significantly from the consensus Ntn hydrolase topology. The DmpA structure thus characterises a new subfamily, but supports the common catalytic mechanism for these enzymes suggesting an evolutionary relationship
The repertoire of λ light chains causing predominant amyloid heart involvement and identification of a preferentially involved germline gene, IGLV1-44
Monoclonal Ig light chains (LC) can be responsible for pathologic conditions in humans, as in systemic amyloid light amyloidosis. Protean clinical manifestations characterize this disorder with the most varied combination of symptoms generated by different degrees of diverse organ involvement. Kidney and heart are most frequently interested, with major heart involvement as the most relevant prognostic factor. The identification of the underlying mechanism involved in organ targeting is of major relevance for the pathobiology of this disorder. To this aim, we characterized the repertoire of variable region germline genes of λ LC preferentially targeting the heart and compared it with the repertoire of LC that do not in a case-control study. We found that the repertoires were highly restricted, showing preferential use of the same few germline genes but with a different frequency pattern. A single gene, IGVL1-44, was found associated with a 5-fold increase in the odds of dominant heart involvement (after adjusting for confounders in a multivariable logistic model). These results support an involvement of LC genetics in the determination of organ targeting. Study of the characteristics of IGVL1-44-LC with, and of the minority without, heart involvement might lead to identification of LC/tissue interactions
Characterization of immunoglobulin variable regions of two human pathogenic monoclonal cryocrystalglobulins
Cold-precipitating monoclonal immunoglobulins can rarely aggregate in form of crystals (cryocrystalglobulins) and cause serious clinical manifestations. The structural basis underlying this phenomenon remains to be defined. This study was undertaken to provide the first characterization of the heavy (VH) and light chain (VL) variable regions of two human pathogenic cryocrystalglobulins. The immunoglobulins used different heavy and light chain constant regions and germline gene fragments, underwent high degrees of somatic hypermutation, and showed distributions of replacement and silent nucleotide changes suggestive of antigenic selection. Primary sequences analyses and computer-generated modeling identified a positive charge and the introduction of unusual hydrophobic residues in exposed areas of VH and VL. In particular, a rare replacement of a polar residue with proline is shared at the beginning of the VH complementarity-determining region 2, and this residue might be involved in intermolecular contacts
Structural features of two monoclonal cryocrystalglobulins causing a rheumatic syndrome with vasculitis
Characterization of immunoglobulin variable regions of two human pathogenic monoclonal cryocrystalglobulins
Cold-precipitating monoclonal immunoglobulins can rarely aggregate in form of crystals (cryocrystalglobulins) and cause serious clinical manifestations. The structural basis underlying this phenomenon remains to be defined. This study was undertaken to provide the first characterization of the heavy (VH) and light chain (VL) variable regions of two human pathogenic cryocrystalglobulins. The immunoglobulins used different heavy and light chain constant regions and germline gene fragments, underwent high degrees of somatic hypermutation, and showed distributions of replacement and silent nucleotide changes suggestive of antigenic selection. Primary sequences analyses and computer-generated modeling identified a positive charge and the introduction of unusual hydrophobic residues in exposed areas of VH and VL. In particular, a rare replacement of a polar residue with proline is shared at the beginning of the VH complementarity-determining region 2, and this residue might be involved in intermolecular contacts